Prevalence of Antibody to Hepatitis E Virus among Rodents ...
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Prevalence of Antibody to Hepatitis E Virus among Rodents in the Prevalence of Antibody to Hepatitis E Virus among Rodents in the
United States United States
Michael O. Favorov
Michael Y. Kosoy
Sergei A. Tsarev
James E. Childs Centers for Disease Control and Prevention, Atlanta, [email protected]
Harold S. Margolis
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449
Prevalence of Antibody to Hepatitis E Virus among Rodents in the United States Michael O. Favorov,1'3 Michael Y. Kosoy,2 Sergei A. Tsarev,4 James E. Childs,2 and Harold S. Margolis1
1Hepatitis Branch and 2 Viral and Rickettsial Zoonoses Branch, Division of Viral and Rickettsial Diseases, National Center
for Infectious Diseases, and 3Division of International Health, Epidemiology Program Office, Centers for Disease Control
and Prevention, Atlanta, Georgia; 4Department of Virus Diseases, Walter Reed Army Institute of Research, Washington, DC
The recent identification of antibody to hepatitis E virus (HEV) in pigs, sheep, and cattle and characterization of an HEV isolated from domestic pigs suggest animal reservoirs for this virus. To investigate whether rodents might be a natural reservoir of HEV, the prevalence of anti-HEV was determined among a variety of species throughout the United States. Serum samples were obtained from 806 rodents of 26 species in 15 genera. Anti-HEV prevalence was assessed by 2 EIAs (mosaic protein- and 55-kDa protein-based), which gave concordant results. The highest prevalence of antibody was found in the genus Rattus (59.707o; 166/278). Overall, rodents from urban habitats had a significantly higher prevalence of anti-HEV than did animals captured from rural areas. A high prevalence of anti-HEV was found in animals captured on mainland versus barrier islands. The results from this study provide convincing evidence of widespread HEV or HEV-like infection in rodents of the United States.
Hepatitis E virus (HEV) infection has been shown to be the cause of many large outbreaks of enterically transmitted hepa- titis over the last 4 decades. Those parts of the world in which outbreaks have occurred include the Indian subcontinent, China, Africa, the Middle East, and Mexico. Sporadic cases of
hepatitis E occur at a relatively high rate in many countries in these regions during intraepidemic periods. In countries where outbreaks have not been documented, cases of hepatitis E occur
primarily among travelers returning from regions in which
hepatitis E is endemic. However, sporadic cases have occurred in persons without a history of travel, and the mode of HEV transmission is not certain [1-7].
Epidemiologic studies indicate that HEV is transmitted by the fecal-oral route and that contaminated water has been the
primary source of infection. However, several aspects of the
epidemiology of HEV infection are not consistent with that of other enterically transmitted viral infections in developing countries. For instance, the age-specific incidence of infection
peaks among young adults rather than young children [4, 8-11]. Also, low secondary attack rates have been observed in house- holds with cases of hepatitis E, in contrast to the high rates of household transmission observed for hepatitis A [6, 12] and other enterically transmitted infections. These findings raise the
Received 23 July 1999; revised 8 October 1999; electronically published 14 February 2000.
Reprints or correspondence: Dr. Michael O. Favorov, 2877 Brandywine Road, M/S K72, Atlanta, GA 30341 ([email protected]).
The Journal of Infectious Diseases 2000; 181:449-55 ? 2000 by the Infectious Diseases Society of America. All rights reserved. 0022-1899/2000/18102-0006502.00
question as to whether humans are the primary source or res- ervoir of HEV.
In contrast to other hepatitis viruses, experimental models of infection in animals other than nonhuman primates have been established. Experimental infections have been established in pigs, sheep, and laboratory rats [13, 14]. The recent identi- fication of antibody to HEV in pigs, sheep, and cattle [15] and the isolation and characterization of an HEV from domestic
pigs that is similar to human HEV [16, 17] suggest that animal reservoirs may exist for this virus.
To investigate whether rodents might be a natural reservoir of HEV or HEV-like viruses, we determined the prevalence of HEV infection, as measured by anti-HEV, among a variety of rodent species captured throughout the United States.
Materials and Methods
Rodent populations. Rodents belonging to 26 species in 15 genera were collected during 1994-1998 from 21 sites in 13 states: Alabama {n = 8 rodents), Arizona {n = 30), Colorado {n = 88), Florida (n = 113), Georgia (n = 151), Louisiana (n = 33), Maryland (n = 127), Nevada (n = 8), North Carolina (n = 72), New Mexico (n = 60), New York {n = 24), Pennsylvania {n = 67), and Texas {n = 25). Sites sampled included 6 urban locations {n = 256 rodents) and 15 rural sites that consisted of various types of habitats {n =
550). Protocols for blood collection followed those of Mills et al. [18],
and samples were stored at -70oC until tested. Detection oflgG anti-HE V. Serum samples were tested for anti-
HEV by use of 2 EIAs, each of which used a different recombinant- expressed HEV antigen. Each serum specimen {n = 806) was tested by EI A that used a mosaic protein (MPr) composed of recombinant
450 Favorov et al. JID 2000; 181 (February)
Table 1. Demographic characteristics of rodents tested for antibody to hepatitis E virus infection, United States, 1994-1998.
Genus and species (common name) No. VoOf total State (no.)
Clethrionomys gapperi (boreal red-backed vole) 6 Citellus
mexicanus (Mexican ground squirrel) 2
variegatus (rock squirrel) 1 Mus musculus (house mouse) 14 Microtus pennsylvanicus (meadow vole) 9 Neotoma
albigula (white-throated wood rat) 22 mexicana (Mexican wood rat) 84
micropus (southern plains wood rat) 8
Onychomys leucogaster (grasshopper mouse) 1
Ochrotomys nuttalli (golden mouse) 11
Oryzomys palustris (rice rat) 41
Perognathus penicillatus (desert pocket mouse) 10
Peromyscus boylei (brush mouse) 24
difficilis (rock mouse) 3 eremicus (cactus mouse) 7
gossiypinus (cotton mouse) 4
leucopus (white-footed mouse) 53 maniculatus (deer mouse) 91
polionotus (oldfield mouse) 3 truei (pinon mouse) 15
Pitymus pinetorum (pine vole) 2 Rattus
norvegicus (Norway rat) 197 rattus (black rat) 81
Sigmodon hispidus (cotton rat) 113 Sciurus carolinensis (eastern gray squirrel) 2
Zapus hudsonius (meadow jumping mouse) 2 Total 806
0.7 North Carolina (6)
0.2 Texas (2) 0.1 New Mexico (1) 1.7 Alabama (3), Georgia (7), Texas (4) 1.1 Pennsylvania (9)
2.7 Arizona (1), New Mexico (21) 10.4 Colorado (84) 1.0 Texas (8) 0.1 New Mexico (1) 1.4 Georgia (3), North Carolina (8) 5.1 Florida (12), Georgia (29) 1.3 Arizona (10)
3 Arizona (9), New Mexico (15) 0.4 Colorado (3) 0.9 Arizona (6), New Mexico (1) 0.5 Florida (1), Georgia (3) 6.6 Alabama (2), Arizona (2), Georgia (12), North Carolina (18), Pennsylvania (19)
11.3 Arizona (1), Colorado (1), Georgia (5), North Carolina (40), Pennsylvania (37), New Mexico (7) 0.4 Georgia (3) 1.9 Arizona (1), New Mexico (14) 0.2 Georgia (2)
24.5 Alabama (1), Florida (1), Georgia (10), Louisiana (28), Maryland (127), Nevada (8), New York (22) 10.1 Alabama (1), Florida (36), Georgia (28), Texas (11), Louisiana (5) 14 Alabama (1), Florida (63), Georgia (49) 0.2 New York (2) 0.2 Pennsylvania (2)
100
proteins from immunoreactive epitopes of HEV open-reading frame (ORF) 2 and ORF 3 [19,20]. Those specimens with adequate volume {n = 612) were also tested for anti-HEV by an EIA for which the antigen was a recombinant 55-kDa ORF 2 protein ex- pressed by baculovirus in insect cells (55KAg) [21].
Both EIAs were modified from those described elsewhere [20, 21] in that horseradish peroxidase-conjugated rabbit anti-rat IgG (Boehringer Mannheim, Indianapolis), diluted 1 : 1000, was used to detect anti-HEV, and serum specimens were diluted to 1 : 50 in PBS, pH 7.4, supplemented with 1007o normal goat serum, Wo bo- vine serum albumin, and 0.010Zo Tween 20.
Cutoff values to define an initially reactive specimen were derived from the frequency distribution of optical density (OD) values ob- tained from 61 randomly selected Norway rats. The OD cutoff for the MPr assay was 0.110, which approximated the mean value (0.01) of the negative specimens 4-3.2 SD units (SD = 0.028). The cutoff for the 55KAg assay was 0.166, which approximated the mean value (0.025) of the negative specimens +3.2 SD units (SD = 0.044).
Serum specimens {n = 5) from rats negative for anti-HEV in both EIAs were pooled and used as a standard negative control. A standard positive control was produced from pooled serum speci- mens of guinea pigs {n ̂ 2) immunized with affinity-purified MPr antigen [19]. When each assay was performed, the OD value of the standard positive control at a 1 : 50 dilution had to be ^0.5, and the OD value of the standard negative control had to be 0.01-0.07 for the test results to be considered valid.
Immunoblot analysis. Selected specimens were analyzed by im-
munoblot to confirm the specificity of antibody reactivity to the mosaic protein used as the antigen in the MPr assay. A recombinant fusion mosaic protein [19] was subjected to SDS-PAGE, and the separated proteins were transblotted to BAS 83 nitrocellulose (Schleicher 8l Schuell, Keene, NH) by means of a TE70 SemiPhor (Hoefer Scientific Instruments, San Francisco). The immunoblot assay conditions were used as described elsewhere [2].
Statistical analyses. For univariate and stratified analyses, sta- tistical testing was done by use of the Pearson test, the Mantel- Haenszel test, or the test for trend, as appropriate. Statistical sig- nificance and relative risk estimates were determined by calculating P values with Yates's correction factor, exact 950Zo confidence in- terval (CIs), or Taylor series 9507o CIs, as appropriate. Logistic regression analysis was conducted by use of LOGIST, a procedure accessible through the SAS system (SAS Institute, Cary, NC).
Results
Rodent captures. Serum samples were obtained from 806 rodents of 26 species in 15 genera (table 1). Urban sites provided 256 animals (31.807o), of which the majority (n = 196, 76.60Zo) were Norway rats (Rattus norvegicus) or black rats Rattus rattus (n = 53, 20.70Zo). The Norway rat was the most common
species captured in Baltimore, New Orleans, Reno, and New York City, whereas R. rattus was the most common species captured in Atlanta and Miami (table 2). The remainder of rats
Table
2.
Prevalence
of antibody
to hepatitis
E virus
(HEV)
among
rodents
from
urban
and
rural
areas
as detected
by recombinant
mosaic
protein,
United
States.
State
City
or county
Year(s)
Total
no.
tested
Genus
and
species
(no.
tested)
Total
no.
(0Zo)
anti-HEV-positive
Genus
and
species
(no.
anti-HEV-postive)
Urban
areas
Georgia
Atlanta
1994
43
Maryland
Baltimore
1995
81
Maryland
Baltimore
1997
46
Florida
Miami
1997
21
Louisiana
New
Orleans
1995
33
Nevada
Reno
1994
8
New
York
New
York
1997
24
Total
256
Rural
areas
Alabama
Chilton
1996
8
Arizona
Yavapai
1995
30
Colorado
Larimer
1997-1998
88
Florida
Dade,
Nassau
1994,
1996
92
Georgia
Barrow,
Chatham,
1994-1995
108
Walker,
Walton
North
Carolina
Macon
1996
72
New
Mexico
McKinley,
1995
60
Socorro,
Taos
Pennsylvania
Monroe
1996
67
Texas
Kleberg
1994
25
Total
550
Peromyscus
leucopus
(2),
Rattus
norvegicus
(10),
Rattus
rattus
(28),
Sigmodon
hispidus
(3)
Rattus
norvegicus
(81)
Rattus
norvegicus
(46)
Rattus
rattus
(20),
Rattus
norvegicus
(1)
Rattus
norvegicus
(28),
Rattus
rattus
(5)
Rattus
norvegicus
(8)
Rattus
norvegicus
(22),
Sciurus
carolinensis
(2)
Rattus
norvegicus
(196)
Rattus
rattus
(53)
Sigmodon
hispidus
(3)
Other
species
(4)
Mus
musculus
(3),
Peromyscus
leucopus
(2),
Rattus
norvegicus
(1),
Rattus
rattus
(1),
Sigmodon
hispidus
(1)
Neotoma
albigula
(1);
Perognathus
penicillatus
(10);
Peromyscus
species:
P. boy
lei (9),
P. eremicus
(6),
P. leucopus
(2),
P. maniculatus
(1),
P. truei
(1)
Neotoma
mexicana
(84),
Peromyscus
difficilis
(3),
Peromyscus
maniculatus
(1)
Peromyscus
gossiypinus
(1),
Oryzomys
palustris
(12),
Rattus
rattus
(16),
Sigmodon
hispidus
(63)
Mus
musculus
(7);
Ochrotomys
nuttalli
(3);
Oryzomys
palustris
(29);
Pero-
myscus
species:
P. gossiypinus
(3),
P. leucopus
(10),
P. maniculatus
(5),
P. polionotus
(3);
Pitymus
pinetorum
(2);
Sigmodon
hispidus
(46)
Clethrionomys
gapperi
(6),
Ochrotomys
nuttalli
(8),
Peromyscus
leucopus
(18),
Peromyscus
maniculatus
(40)
Citellus
variegatus
(1);
Neotoma
albigula
(21);
Onychomys
leucogaster
(1);
Peromyscus
species:
P. boy
lei (15),
P. eremicus
(1),
P. maniculatus
(7),
P. truei
(14)
Microtus
pennsylvanicus
(9),
Peromyscus
leucopus
(19),
Peromyscus
manicula-
tus
(37),
Zapus
hudsonius
(2)
Citellus
mexicanus
(2),
Mus
musculus
(4),
Neotoma
micropus
(8),
Rattus
rattus
(11)
Clethrionomys
gapperi
(6)
Mus
musculus
(14)
Neotoma
albigula
(22)
Neotoma
mexicana
(84)
Neotoma
micropus
(8)
Oryzomys
palustris
(41)
Peromyscus
boylei
(24)
Peromyscus
eremicus
(7)
Peromyscus
leucopus
(50)
Peromyscus
maniculatus
(91)
Rattus
norvegicus
(1)
/?a??M5
ra^M^
(28)
Sigmodon
hispidus
(110)
Other
species
(64)
19 (44.2)
i*. norvegicus
(3),
i*. rtf/fws
(15),
S. /iw/wtfitf
(1)
63 (77.8)
R norvegicus
(63)
42 (91.3)
R. norvegicus
(42)
4 (19)
R. rattus
(3),
/?. norvegicus
(1)
10 (30.3)
/?. norvegicus
(8),
tf. ra/ft?
(2)
2 (25)
R. norvegicus
(2)
15(62.5)
R. norvegicus
{\ 5)
134
(68.4) 20 (37.7)
1 (33.3)
0 1 (12.5)
R. norvegicus
(1)
6 (20)
N albigula
(!),/>
foyfe/
(2),
/? eremicus
(3)
49 (55.7)
TV. mexicana
(48),
? maniculatm
42 (45.2)
a palustris
(10),
it raffttf
(8),
18 (16.7)
11 (16.2)
12 (20)
3 (4.5)
4(16) 4 (66.7)
2 (14.3)
13 (59.1)
48 (57.1)
1 (12.5)
10 (24.4)
2 (8.3)
3 (42.9)
5(10) 10(11) 1 (100)
11 (39.3)
36 (32.7)
0
S. hispidus
(24)
M.
musculus
(2),
P. leucopus
(2),
P. maniculatus
(2),
S. hispidus
(12)
C. gapperi
(4),
P. leucopus
(2),
P. maniculatus
(5)
N. albigula
(12)
/! leucopus
{\),
P maniculatus
(2)
TV. micropus
(1),
/?. rar/ws
(3)
452 Favorov et al. JID 2000; 181 (February)
captured in urban areas belonged to 3 other species (Pero- myscus leucopus, Sciurus carolinensis, and Sigmodon hispidus).
Rural sites consisting of natural habitat were sampled in 9 states and provided 550 rodents of 25 species (table 2). The most common species varied with the type of habitat and in- cluded white-throated wood rats {Neotoma albigula; n = 22) and mice of the genus Peromyscus in = 148) from arid habitats in Arizona and New Mexico; Mexican wood rats (Neotoma mexi-
cana) from Colorado; white-footed mice (P. leucopus) and deer mice (Peromyscus maniculatus) from forest habitats of Georgia, North Carolina, and Pennsylvania; meadow voles (Microtus pennsylvanicus) from grassy areas in Pennsylvania; and cotton rats (S. hispidus) and rice rats (Oryzomys palustris) from
grassy and marshy areas of Georgia and Florida. EI A performance. The MPr assay was positive for anti-
HEV in 303 (380Zo) of 806 rodents. Antibody was detected by the 55KAg assay in 244 (400Zo) of the 612 rodents tested. Overall, the prevalence of anti-HEV detected by the 2 assays was not different (odds ratio [OR], 0.95; 950Zo CI, 0.83-1.08; i^.4); however, there were differences in the genus Rattus (table 3). Among these rodents, prevalence of anti-HEV among animals tested with the 55KAg assay was 76.40Zo (146/191), compared with 59.70Zo (166/278) for the same animals tested with the MPr
assay (OR, 2.19; 950Zo CI, 1.4-3.4; i^.OOl). For animals in all genera tested by both assays, the concor-
dance for both positive and negative test results was 88.90Zo
(544/612), and for specimens positive in either assay the con- cordance was 74.70Zo (201/269) (table 3). When anti-HEV
prevalence was defined as reactivity in both assays (330Zo; 201/
612), this did not differ from the prevalence obtained by pos- itivity in the MPr assay alone (380Zo; 303/806) (OR, 1.24; 950Zo
CI, 0.99-1.6; P = .07) and was less than the seroreactivity by 55KAg alone (40.00Zo; 244/612) (OR, 1.36; 950Zo CI, 1.1-1.7; P = .01). When anti-HEV prevalence was defined on the basis of seropositivity in either assay (44.00Zo; 269/612), this exceeded the anti-HEV prevalence by MPr alone (OR, 1.3; 950Zo CI, 1.04-1.62; P = .02) but was not different from prevalence as defined by seropositivity in the 55KAg assay (OR, 1.18; 950Zo
CI, 0.99-1.49; P^ . 16). Immunoblot analysis. Of 81 Norway rats tested in the MPr
assay, serum specimens from 26 were randomly selected for further analysis of antibody specificity by immunoblot analysis. Among 22 serum specimens positive by the MPr assay, 21
(95.50Zo) were positive by immunoblot analysis of the MPr. All 4 EIA-negative serum samples were negative by immunoblot
testing. Antibody prevalence. Serum samples from 192 rodents were
not of sufficient quantity to be tested by both the 55KAg and MPr assays. Of those animals not tested by the former assay, there was no significant difference in trap location, species, or
year of collection from animals tested by both assays (data not
shown). Because the anti-HEV prevalence results obtained by the 2 EIAs were statistically similar and generally gave con- cordant results, subsequent analysis was limited to antibody results obtained for all animals tested with the MPr assay. The
highest prevalence of antibody was found among the genus Rattus (59.70Zo; 166/278), with a significantly higher prevalence among R. norvegicus (68.50Zo; 135/197) than R. rattus (38.30Zo; 31/81) (OR, 3.5; 950Zo CI, 1.98-6.25; 7^.0001). The majority of Rattus specimens tested came from urban sites (table 2), although the prevalence of anti-HEV antibody (41.30Zo; 12/29) in Rattus species from rural locations (table 2) was similar to that of urban sites (OR, 3.5; 950Zo CI, 0.9^.9; P ^ .08). Among rodents captured from rural environments, 146 (26.50Zo) of 550 were antibody-positive and belonged to 13 species (table 2). Of the seropositive animals from rural sites, the majority (67.10Zo; 98/146) belonged to 2 genera: Neotoma (N. albigula, N. mexi-
cana, and Neotoma micropus), with 54.40Zo (62/114) positive, and Sigmodon (S. hispidus), with 32.70Zo (36/110) positive. Al-
though only 3 animals were obtained from an urban environ-
ment, antibody prevalence in S. hispidus from urban sites (330Zo) was the same as that from rural locations (330Zo) (table 2). Of animals belonging to 6 species of Peromyscus, however, only 19 (9.80Zo) of 194 were antibody-positive, although these were
spread among 4 species (P. leucopus, P. maniculatus, P. boylei, and P. eremicus). Of the remaining rodents, seropositive ani- mals were identified in 3 additional species: the rice rat, O.
palustris (10/41; 240Zo); the red-backed vole, Clethrionomys gap- peri (4/6; 670Zo); and the house mouse, Mus musculus (2/14; 14.30Zo).
Table 3. Reactivity to antibody to hepatitis E virus (HEV) by EIA based on recombinant HEV antigens (mosaic protein [MPr]; 55-kDa protein [55KAg]) among rodents, by genus.
Reactivity to HEV antigens
Rodent Positive Positive P, MPr Positive by both Positive by either P, both
genus by MPr by 55KAg vs. 55KAg MPr and 55KAg MPr or 55KAg vs. either
Neotoma 62/113(55) 12/22(55) 1 9/22(41) 16/22(73) .08
Oryzomys 10/41 (24) 15/41 (37) .3 10/41 (24) 15/41 (37) .3
Peromyscus 21/200(10) 22/196(11) .6 14/192(7) 27/192(14) .05 Rattus 166/278 (60) 146/191 (76) <.001 134/191 (70) 155/191 (81) .02
Sigmodon 37/112(33) 40/109(37) .7 28/109(26) 48/109(44) .007 Other 7/62(12) 9/53(17) .5 6/53(11) 10/53(19) .4
Total 303/806(38) 244/612(40) .43 201/612(33) 269/612(44) <.001
NOTE. Data are no./total tested (07o).
JID2000;181 (February) Prevalence of Anti-HEV among US Rodents 453
Demographic characteristics. The prevalence of anti-HEV-
positive animals was ^-fold higher among rodents captured from urban areas (60.50Zo; 155/256) than among those origi- nating from rural areas (26.50Zo; 146/550) (OR, 4.2; 950Zo CI, 3-5.9; /^ .001), primarily because of the contribution of Nor-
way rats to the urban sample. In rural habitats of the southeastern region of the United
States, the most commonly seropositive rodent was the cotton rat (S. hispidus). This rodent had an overall anti-HEV prev- alence of (32.70Zo; 37/113) and constituted 60.00Zo (36/60) of the animals reactive to MPr in Florida and Georgia. Wood rats
(Neotoma species) contributed the highest proportion (95/106; 89.60Zo) of seropositive animals in the Southwest (Arizona, Col-
orado, New Mexico), with the highest anti-HEV prevalence in N. albigula (13/22; 59.10Zo) and N. mexicana (48/84; 57.10Zo).
Differences in prevalence of anti-HEV were also observed between rodents captured on the mainland versus animals cap- tured on barrier islands. Of 29 rice rats (O. palustris) captured from 2 neighboring islands (Cockspur and McQueen Islands, Chatham County, GA), none was anti-HEV-positive, whereas all 10 rodents of the same species captured from the mainland of southern Florida was positive (i^ .001). Similarly, whereas none of 18 cotton rats from Amelia Island in northern Florida were positive, 8 (32.00Zo) of 25 cotton rats captured from a mainland site (Social Circle, Walton County, GA) were positive (i^.Ol).
The prevalence of antibody differed from year to year during the 5-year collection period (analysis of trend: P'C.OOl; x2 -
134; df=4). Antibody prevalence significantly varied by year when analyzed by species: Among Neotoma species, prevalence was 680Zo (40/59) in 1997 and 140Zo (1/7) in 1994; among Ory- zomys species, 100.00Zo (10/10) in 1994 and 0 (0/20) in 1995; among Rattus species, 64.00Zo (73/114) in 1995 and 480Zo (46/95) in 1994; and among Sigmodon species, 51.00Zo (25/49) in 1995 and 0 (0/17) in 1996. Much of this variation may be due to the selection of different sampling sites in different years.
Logistic regression analysis. Factors that univariate anal-
ysis showed were statistically associated with anti-HEV sero-
reactivity among rodents were included in a logistic regression model. In this analysis, differences in anti-HEV activity by spe- cies, location (e.g., islands vs. mainland), and by assay showed that urban-rural variations were independently associated with anti-HEV seroprevalence. Year-to-year prevalences of anti- HEV among animals and by species were not significantly as- sociated with anti-HEV seroreactivity.
Discussion
This study demonstrated the widespread occurrence and high prevalence of antibody reactive with HEV recombinant anti-
gens among rodents captured in a variety of locations in the United States. Although antibody prevalence varied across spe- cies and habitats, infected animals were found in virtually all
of the locations sampled (figure 1). These data provide strong evidence that an agent identical or closely related to HEV is
circulating among rodent populations throughout the United States.
The 2 antigens used in the different HEV EIAs provided consistent results among those animals tested by both antigens. The concordance of the serologic findings between the 2 assays was high (88.90Zo). This high level of agreement was exceptional, as simultaneous testing of human serum specimens by these same 2 assays has shown a high degree of discordance [22, 23]. In addition, the antibodies in a subset of animals positive by the EIAs showed specific activity to purified HEV proteins in immunoblot assays. The single specimen positive in the EIA but negative by immunoblot probably reflected a low titer of
antibody not detected by immunoblot assay, which has a lower
sensitivity [2]. The high prevalence of antibody found among rodents (440Zo
by either antigen, 330Zo by both antigens) indicated a high rate of infection with HEV or an HEV-like agent. Although it is
possible that the anti-HEV detected in these animals repre- sented a false-positive result, this is highly unlikely because of the specificity of the immunoblot data and the results of ex-
perimental HEV infection in rodents [24]. In addition, an HEV strain has been isolated from rodents captured in Nepal that was similar to HEV sequences obtained from patients with HEV infection in the same country [25]. The high prevalence of seropositive rodents, their widespread distribution, and the
consistency of serologic findings support the hypothesis that rodents could serve as a reservoir of HEV or HEV-like viruses and that transmission to humans could occur in the right setting or set of circumstances. Future efforts must characterize the rodent HEV, define the epidemiology of HEV infection among rodents, and determine the relationship of this infection to humans.
Seropositive animals were found in all rodent communities in which sufficient numbers of animals were tested; however, significant variation in the prevalence of IgG antibody reactive with HEV was apparent. The highest prevalence occurred in urban areas among rats of the genus Rattus, whereas Pero-
myscus species had lower prevalence of antibody reactive to HEV antigens, regardless of locale. The reason for the high prevalence of anti-HEV among rats sampled from urban en- vironments is unclear. Norway rats reached very high popu- lation densities in some urban locations, which may facilitate HEV transmission. It is interesting to note that rodents of the
genera Rattus and Mus were introduced into the New World. The origin of the genus Rattus is a Central Asian area in which
hepatitis E in humans is highly endemic [26]. As HEV isolates or sequences become available from rodent sources in the New
World, it will be interesting to determine if the HEV-like viruses introduced to rodents are similar to Old World viruses. Recently identified HEV in pigs from the United States shared ~790Za-800Zo nucleotide and 900Zo-920Zo amino acid sequence iden-
454 Favorov et al. JID 2000; 181 (February)
Sigmadon Neotoma Orywmys Peromyscus
*^ O 6-15* ^30* >30% ArczofS.hispidus ' * # # Ait* of Neotoma albigula and N-mexicana
R.norvegicus R.rattus
*c20* 20-50* 51-80* <80%
Figure 1. Distribution and prevalence of antibodies to hepatitis E virus among rats of genus Rattus (bottom) and rodents of 4 genera (top)
tity with human HEV strains; swine HEV cross-reacted with
antibody to the human HEV antigens [27]. The Norway and black rats are already recognized threats to human health be- cause of their association with a number of zoonotic infections, including plague, Seoul virus (genus Hantavirus), leptospirosis, and murine typhus [28].
The presence of anti-HEV among rodents indigenous to the United States and living in natural habitats suggests that in- fection occurs in a wide range of New World rodent species, such as Neotoma in the Southwest and cotton rats (S. hispidus, O. palustris) in the southeastern United States. It is also known that infection in rodents can be focal [28]. Particularly striking was the complete lack of anti-HEV among S. hispidus and O.
palustris on islands, in contrast with seropositivity among an- imals of both species on the mainland. This result suggests either that the population of rodents on these islands is too
small to sustain HEV transmission or that the virus was never introduced into those settings. Seropositive rodents were found in the Sevilleta National Wildlife Refuge, New Mexico. This
finding provides a good example that HEV-related viruses may exist in remote areas that are well removed from humans and domestic animals. The exact nature of the HEV or HEV-like virus associated with rodents awaits their isolation and char- acterization. Nevertheless, the results from this study provide convincing evidence of widespread HEV or HEV-like infection in rodents of the United States.
Acknowledgments
We thank Pat Coleman, Karen McCaustland, Terrence Chorba, Howard Fields, and Jim Mills (Centers for Disease Control and Pre- vention [CDC], Atlanta), Gregory Glass (John Hopkins University,
JID 2000; 181 (February) Prevalence of Anti-HEV among US Rodents 455
Baltimore), Gary Moupin (CDC, Fort Collins, CO), and Terry Yates
(University of New Mexico, Albuquerque) for help in various aspects of the study.
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